RU2336800C1 - Vacuum cleaner and dust separator - Google Patents

Abstract

FIELD: everyday practice articles.

SUBSTANCE: invention refers to vacuum cleaners. Vacuum cleaner contains main body, dust collector with contaminant storage section, first dust separator arranged in dust collector, and cover attached to first dust separator. External wall of first dust separator parts contaminant storage section to first and second sections. Additionally vacuum cleaner can contain second dust separator. Dust separator contains dust collector, cyclone mounted in dust collector and cover attached to cyclone and detachable from dust collector with cyclone.

EFFECT: prevention of recurring contamination at contaminants discharge.

22 cl, 7 dwg

Description

FIELD OF THE INVENTION

The present invention relates to a vacuum cleaner and a dust separating device of a vacuum cleaner, and more particularly to a dust separating device having an improved design for easily unloading collected contaminants, and to a vacuum cleaner containing a dust separating device.

Description of the prior art

Typically, the vacuum cleaner uses the negative pressure generated by the suction motor installed in the main body of the vacuum cleaner, first to suck in air containing contaminants and then filter the contaminants from the air in the main body.

Basically, vacuum cleaners can be divided into container-type vacuum cleaners that contain a suction nozzle provided separately from the main body, and vertical type vacuum cleaners in which the suction nozzle is integral with the main body.

Vacuum cleaners in accordance with the prior art comprise a main body and a dust collecting device that collects contaminant particles separated from air passing into the main body.

The dust collecting device is removably mounted in the main body so that the contaminants stored in the dust collecting device can be easily removed after disconnecting the dust collecting device from the main body.

However, when the dust collector is emptied in accordance with the prior art, the interior that has been cleaned by the vacuum cleaner is subject to re-contamination during the process of separating the dust collector from the main body of the vacuum cleaner or when unloading contaminants from the dust collector.

Thus, when the interior is re-contaminated when the user empties the dust collector, the user must clean the contaminated surface again using a vacuum cleaner or other cleaning devices.

Therefore, it is necessary to create a dust collecting device that prevents re-contamination of the interior of the vacuum cleaner, and which facilitates the discharge of the polluting particles when the user unloads the polluting particles stored in the dust collecting device.

SUMMARY OF THE INVENTION

Therefore, the present invention relates to a vacuum cleaner and a dust separating device of a vacuum cleaner, which essentially eliminate one or more problems caused by the limitations and disadvantages of the prior art.

An object of the present invention is to provide a vacuum cleaner and a dust separator for a vacuum cleaner that allow a user to easily unload contaminants stored in a dust collector, providing enhanced user convenience.

Another objective of the present invention is to provide a vacuum cleaner and a dust separating device of a vacuum cleaner, which provide easy discharge of the polluting particles stored in the dust collecting device, preventing re-pollution of the interior during the discharge of the polluting particles.

Additional advantages, objectives, and features of the present invention will be partially discussed in the following description and partially understood by those skilled in the art after studying the following, or may be studied by practicing the present invention. The objectives and other advantages of the present invention can be realized and achieved due to the design specifically indicated in the description and claims, as well as in the accompanying drawings.

To achieve these goals and other advantages, and in accordance with the purpose of the present invention, as embodied and broadly described herein, a dust separation device is described comprising: a dust collecting container in which a compartment for storing contaminant particles is formed; a dust separation element contained in a dust collecting container; and a lid connected to the dust separation element and used to selectively open and close the compartment for storing contaminant particles, the lid being disconnected from the dust collecting container together with the dust separation element when emptying the dust collecting container.

In another aspect of the present invention, a vacuum cleaner is described, comprising: a dust collecting container in which a plurality of compartments for storing contaminant particles are formed; a first dust separation element located in one of the compartments for storing contaminant particles; a lid connected to the first dust separation element and used to selectively open and close compartments for storing contaminant particles; and a main body with which the dust collecting container is removably connected.

In yet another aspect of the present invention, a vacuum cleaner is described, comprising: a dust collecting container in which a compartment for storing contaminant particles is formed; a first dust separating element located in the dust collecting container and dividing the compartment for storing contaminant particles into a plurality of compartments for storing contaminant particles; a lid connected to the first dust separation element and used to selectively open and close compartments for storing contaminant particles; and a main body with which the dust collecting container is removably connected.

In accordance with the present invention, the dust collecting device for collecting contaminants is separated from the main body of the vacuum cleaner in a sealed state. Thus, the user can fully open the upper part of the dust-collecting container by opening the upper cover to the desired position, thereby preventing re-contamination of the interior of the vacuum-cleaned room, and increasing user convenience.

Also, a first cyclone element is installed in the dust container and a second cyclone element is mounted in the main body of the vacuum cleaner, so that when the collected contaminants are discharged from the dust container, only the dust container can be removed from the main body, reducing the weight of the dust container and providing ease of use.

In addition, by simultaneously opening and closing the first and second storage compartments with the top cover installed in the upper part of the tank, the discharge of contaminants becomes easier.

In addition, since the first and second compartments for storing contaminants are separated by the outer wall of the first cyclone, which can be disconnected with the top cover when cleaning the inside of the dust container, the inconvenience caused by its internal structure can be prevented, thereby facilitating cleaning of the dust container .

You must understand that both the specified General description and the following detailed description of the present invention are illustrative and explanatory and are intended to provide an additional explanation of the present invention, as claimed.

Brief Description of the Drawings

The accompanying drawings, which are included to provide a further understanding of the present invention and form part of this application, show an embodiment (s) of the present invention and together with the description serve to explain the principle of the present invention. In the drawings:

1 is a perspective view illustrating a vacuum cleaner and a dust collecting device disconnected from a vacuum cleaner in accordance with a first embodiment of the present invention;

2 is a perspective view illustrating a vacuum cleaner and a dust collecting device installed in a vacuum cleaner in accordance with a first embodiment of the present invention;

FIG. 3 is a schematic sectional view illustrating a dust collecting device according to a first embodiment of the present invention; FIG.

4 is a sectional view illustrating a dust collecting device in accordance with a second embodiment of the present invention;

5 is a perspective view illustrating a vacuum cleaner in accordance with a third embodiment of the present invention;

6 is an exploded perspective view illustrating a dust collecting device according to a third embodiment of the present invention; and

7 is a schematic sectional view illustrating a dust collecting device in accordance with a third embodiment of the present invention.

Detailed description of the present invention

Reference will be made in detail to preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. Where possible, the same reference numbers will be used throughout the drawings to refer to the same or similar elements.

FIG. 1 is a perspective view illustrating a vacuum cleaner and a dust collecting device disconnected from a vacuum cleaner in accordance with a first embodiment of the present invention; FIG. 2 is a perspective view illustrating a vacuum cleaner and a dust collecting device installed in a vacuum cleaner in accordance with a first embodiment an embodiment of the present invention, and FIG. 3 is a schematic sectional view illustrating a dust collecting device in accordance with a first embodiment of the present invention.

As shown in FIGS. 1-3, a vacuum cleaner in accordance with this embodiment of the invention comprises a main body 100 and a dust separation device. The main body 100 comprises a drive unit 110 for generating a suction force, and a dust separation device separates and collects contaminants from the air sucked into the vacuum cleaner.

The vacuum cleaner further comprises a suction nozzle (not shown) for sucking air into the vacuum cleaner and a connecting pipe (not shown) for connecting the suction nozzle to the main body 100.

The suction nozzle and connecting pipe have the same design as the suction nozzle and connecting pipe of a prior art vacuum cleaner. Thus, descriptions of the suction nozzle and connecting tube will be omitted.

In detail, the main body 100 further comprises a suction port 120 and an outlet 190. A suction port 120 is formed in a front lower portion of the main body 100 and is connected to the suction nozzle. An outlet 190 is formed in the side of the main body 100 for discharging air after separating the contaminants from the air using the dust collector 200.

The drive unit 110 comprises a suction motor for generating a suction force for drawing in external air into the vacuum cleaner through the nozzle.

The dust separation device includes a first separation element, such as a first cyclone element 230, and a second separation element, such as a second cyclone element 300. The first cyclone element 230 is contained in the dust collecting device 200, and the second cyclone element 300 is contained in the main body 100. The first the cyclone element 230 separates the contaminants from the air passing into the vacuum cleaner, and then the second cyclone element 300 further separates the pollutants from the air.

In detail, the second cyclone element 300 communicates with the dust collector 200 when installing the dust collector 200 in the main body 100.

The dust collecting device 200 includes a first cyclone element 230 for separating contaminants from the intake air and a dust collecting container 210 detachably connected to the first cyclone element 230.

Preferably, the first cyclone element 230 is removably mounted in the dust container 210 and has a cylindrical outer wall. The first cyclone element 230 first separates the contaminants from the air before the passage of air into the second cyclone element 300.

Meanwhile, the dust collecting container 210 comprises a first air inlet 221 in the upper side. Air flows into the first cyclone element 230 through the first air inlet 221 of the dust collecting container 210 and swirls along the inner wall of the first cyclone element 230. To this end, the first cyclone element 230 comprises a suction opening (not shown) corresponding to the first dust collecting air intake opening 221 capacity 210.

The dust collecting tank 210 stores contaminants separated from the air by the first and second cyclone elements 230 and 300.

In detail, the dust collecting container 210 comprises a first compartment 214 for storing contaminant particles separated by a first cyclone element 230, and a second compartment 216 for storing contaminant particles separated by a second cyclone element 300.

The second pollutant storage compartment 216 communicates with the second cyclone 300 when the dust collector 200 is installed in the main body 100. The pollutants separated from the air by the second cyclone 300 are sent to the second pollutant storage compartment 216 through the pollutant inlet 217 a second compartment 216 for storing contaminants.

In this case, the second compartment 216 for storing contaminant particles can be performed separately from the dust container 210 instead of being executed in the dust container 210.

However, for example, in this embodiment, a second pollutant storage compartment 216 and a first pollutant storage compartment 214 are formed inside the dust collecting container 210.

The dust collecting container 210 comprises a first wall 211 forming a first compartment 214 for storing particulate matter, and a second wall 212 forming together with a first wall 211 a second compartment 216 for storing particulate matter.

That is, the second wall 212 closes a predetermined portion of the first wall 211. Thus, a second compartment 216 for storing contaminant particles is formed on the outer part of the first compartment 214 for storing contaminants.

Since a second contaminant storage compartment 216 is formed outside the first contaminant storage compartment 214, the first contaminant storage compartment 214 may be large in size to receive a large amount of contaminant particles.

Meanwhile, the upper part of the dust collector 210 is open so that contaminants can be removed from the dust collector 210 by turning the dust collector 210 upside down. The top cover 250 is removably connected to the open top of the dust container 210.

In addition, the top cover 250 is connected to the top of the first cyclone element 230, so that the top cover 250 and the first cyclone element 230 can be disconnected from the dust container 210 by removing contaminants from the dust container 210.

The hollow filter element 260 is connected to the top cover 250. The filter element 260 is formed with a plurality of through holes 262 having a predetermined size. The top cover 250 includes a first air outlet 252 after it has passed through the filter element 260.

Therefore, after separating the contaminants from the air in the first cyclone element 230, air leaves the dust collector 200 through the filter element 260 and the first air outlet 252.

Top cover 250 closes and opens both the first and second compartments 214 and 216 for storing contaminants.

Therefore, when the top cover 250 connected to the first cyclone element 230 is disconnected from the dust collecting container 210, the upper part of the dust collecting container 210 is completely open. After that, the contaminants collected in the first and second compartments 214 and 216 for storing the contaminants can be easily discharged by turning the dust container 210 upside down.

That is, when the top cover 250 is disconnected from the dust collecting container 210, both upper parts of the first and second contaminant storage compartments 214 and 216 are open. In this way, the contaminants can be easily discharged from the first and second compartments 214 and 216 for storing the contaminants by turning the dust collecting container 210 upside down.

In this case, the top cover 250 may be disconnected from the dust collecting container 210 to remove contaminants from the dust collecting container 210 after transferring the dust collecting container 210 to the outside or to the garbage bin to prevent contamination of the interior of the building with contaminants removed from the dust collecting container 210.

Preferably, the blocking element 240 may be mounted at the bottom of the first cyclone element 230 to prevent the passage of the contaminants collected in the first compartment 214 for storing the contaminants from dispersion to the first cyclone element 230 due to the swirling movement of air.

In this embodiment, the blocking element 240 may be the bottom wall of the first cyclone element 230 or a separate part attached to the first cyclone element 230.

The blocking element 240 comprises an opening 242 through which the contaminants separated from the air in the first cyclone element 230 are discharged into the first compartment 214 for storing the contaminants.

That is, the contaminants separated from the air in the first cyclone element 230 are moved down to the first compartment 214 for storing the contaminants through an opening 242 formed on the edge of the blocking element 240. Preferably, one or more holes 242 can be formed along a circular path at the edge blocking element 240.

Preferably, the handle 270 can be formed on the outer surface of the dust collecting container 210. In this case, the dust collecting container 210 can easily be connected to or disconnected from the main body 100 using the handle 270. In addition, the dust collecting container 210 can be easily carried using the handle 270.

Meanwhile, the second cyclone element 300 is mounted on the main body 100. The second cyclone element 300 separates the polluting particles from the air once again after the separation of the polluting particles from the air by the first cyclone element 230.

In detail, the main body 100 comprises an installation part 140 for a dust collecting container for installing a dust collecting container 210. A second cyclone element 300 is provided above the mounting part 140 for a dust collecting container.

Preferably, the second cyclone element 300 may be installed in the main body 100 in a stowed position.

As described above, since the second cyclone element 300 is located in the main body 100 in the laid position, interference with other components such as the drive unit 110 can be prevented. Therefore, the efficiency with respect to the use of space and components can be increased, and thus , the dimensions of the vacuum cleaner can be reduced.

In this embodiment, as shown in FIG. 2, the second cyclone element 300 is laid approximately perpendicular to the central axis of the cylindrical first cyclone element 230, and the drive unit 110 is located under the second cyclone element 300.

The second cyclone element 300 may take various forms. Preferably, the second cyclone element 300 may be in a form suitable for separating contaminants from air by centrifugal force. In this embodiment, each cyclone portion of the second cyclone element 300 is conical.

Meanwhile, the connecting channel 170 is located between the first and second cyclone elements 230 and 300 for connecting the first and second cyclone elements 230 and 300.

In detail, one end of the connecting channel 170 is connected to the top cover 250, the other end of the connecting channel 170 is a second air inlet (not shown) of the second cyclone element 300.

When the dust collecting device 200 is mounted on the dust collecting container mounting part 140, an opening 302 for discharging the pollutant particles formed at the end of the second cyclone element 300 is connected to the opening 217 for the intake of the polluting particles of the second compartment 216 for storing the polluting particles.

As described above, the second cyclone element 300 is contained in the main body 100, and the contaminants separated by the second cyclone element 300 are stored in the second pollutant storage compartment 216 formed in the dust collector 200.

In other words, since the second cyclone element 300 is not installed in the dust collector 200, the dust collector 200 can be simple and easy. Thus, the dust collector 200 can be easily detached from the main body 100 to remove collected contaminants.

Meanwhile, it is preferable that the amount of contaminants collected in the first contaminant storage compartment 214 can be seen from the outside.

To this end, the first contaminant storage compartment 214 may include a transparent outer wall that is directly visible from the outside. Therefore, it can be easily determined when it is necessary to empty the dust collector 200, since it is possible to see the inside of the first contaminant storage compartment 214, in which most of the collected contaminant particles are located.

The operation of the vacuum cleaner will be described below.

When the drive unit 110 is driven, the drive unit 110 generates a suction force for drawing in external air containing contaminants into the vacuum cleaner through the suction nozzle.

External air drawn in through the suction nozzle passes into the first air inlet 221 for suctioning the dust collecting device 200 through the suction opening 120 of the main body 100.

Then, air is directed from the first air intake opening 221 to the first cyclone element 230 tangentially to the inner wall of the first cyclone element 230 for swirling in the first cyclone element 230. Therefore, the contaminants contained in the air are separated from the air by centrifugal force and move down by gravity into the first compartment 214 for storing contaminants. The contaminants collected in the first pollutant storage compartment 214 do not flow back to the first cyclone element 230 due to the blocking element 240.

After the primary separation of the contaminants from the air by the first cyclone element 230, air moves upward through the filter element 260 and the first air outlet 252. The air then passes into the second cyclone element 300 through a connecting channel 170 connected to the first air outlet 252.

Then, air is guided by a second air suction hole (not shown) connected to the end of the connecting channel 170 to each cyclone part of the second cyclone element 300 tangentially to the inner wall of the cyclone part. In the second cyclone element 300, the contaminants are secondly separated from the air by centrifugal force and sent to a second compartment 216 for storing the pollutants connected to the end of the second cyclone element 300.

After that, air is sent from the second cyclone element 300 back to the main body 100, in which the fine particulate pollutants are finally separated from the air using a filter (not shown). After passing through the filter, air passes through the drive unit 110 and leaves the main body 100 through the outlet 190.

After collecting a predetermined amount of contaminants in the dust collector 200, the dust collector 200 is disconnected from the main body 100. Then, the top cover 250 to which the first cyclone element 230 is connected is disconnected from the dust collector 210 of the dust collector 200. After that, the dust collector 210 can be easily emptied by turning dust container 210 upside down.

4 is a sectional view illustrating a dust collector 400 in accordance with a second embodiment of the present invention.

As shown in FIG. 4, the dust collecting device 400 of this embodiment comprises a first cyclone element 430 for separating contaminants from the intake air, a top cover 450 connected to the upper part of the first cyclone element 430, and a dust collecting container 410 that is removably connected top cover 450.

In detail, the dust collecting container 410 comprises a first wall 411 and a second wall 412. The first wall 411 forms the lower part of the dust collecting container 410 and has a cylindrical shape. The second wall 412 extends upward from the first wall 411 and forms a space that is larger than the space formed by the first wall 411.

That is, the first and second walls 411 and 412 have different sizes. Thus, a curved portion 413 is formed between the first and second walls 411 and 412. The first cyclone element 430 is stably placed on the curved portion 413.

When the first cyclone element 430 is installed in the dust collecting container 410 and placed on the bent portion 413, the inner space of the dust collecting container 410 is divided into the first and second compartments 414 and 416 for storing contaminants by the first cyclone element 430.

That is, in this embodiment, a dividing wall is not mounted to divide the interior of the dust collecting container 410 into first and second compartments 414 and 416 for storing contaminants. Instead, the interior of the dust container 410 is divided into first and second compartments 414 and 416 for storing contaminants by the outer wall of the first cyclone element 430.

Therefore, when the top cover 450, to which the first cyclone element 430 is connected, is disconnected from the dust collecting container 410 for discharging the pollutants collected in the first and second compartments 414 and 416 for storing the pollutants, the first and second compartments 414 and 416 for storing the pollutants communicate with each other.

That is, since no additional baffle is formed in the dust collecting container 410, the contaminants collected in the dust collecting container 410 can be removed much more easily. In addition, it is easier to clean the dust container 410.

Preferably, the dust collecting container 410 may include a sealing element 440 for sealing the gap between the first and second compartments 414 and 416 for storing contaminants.

In detail, the sealing member 440 may be mounted on the bent portion 413 or the first cyclone member 430.

Preferably, the curved portion 413 may be rounded with a predetermined curvature. In this case, when the top cover 450 is disconnected from the dust collecting container 410, the contaminants collected in the second contaminant storage compartment 416 can easily slide down into the first contaminant storage compartment 414 along the curved portion 413. Therefore, the contaminants can be easily removed from the dust container 410 by turning the dust container 410 upside down.

In addition, since the open upper portion of the dust collecting container 410 is larger than the first dust storage compartment 414, the pollution particles can more easily be removed from the dust collecting container 410.

FIG. 5 is a perspective view illustrating a vacuum cleaner in accordance with a third embodiment of the present invention, FIG. 6 is a perspective exploded view illustrating a dust collecting device in accordance with a third embodiment of the present invention, and FIG. 7 is a schematic view in sectional view illustrating a dust collecting device in accordance with a third embodiment of the present invention.

As shown in FIGS. 5-7, the vacuum cleaner of this embodiment comprises a main body 500 and a dust collecting device 600 installed in the main body 500.

In detail, the main body 500 includes a suction port 510 and an outlet (not shown). A suction port 510 is formed in the front lower part of the main body 500 and is connected to a suction nozzle (not shown), and an exhaust port is formed in the side of the main body 500 to release air from the vacuum cleaner after separation of the contaminants from the air.

The main body 500 further comprises a second dust separation element, such as a second cyclone element 700, in the upper part. When installing the dust collecting device 600 in the main body 500, the second cyclone element 700 communicates with the dust collecting device 600.

The remaining parts of the main body 500 essentially have the same structures as the remaining parts of the main body 100. Thus, their descriptions will be omitted.

The dust collecting device 600 is removably connected to the front of the main body 500. A separating element 520 is provided in the front upper part of the main body 500 for use when disconnecting the dust collecting device 600 from the main body 500.

In addition, a handle 530 is formed on the upper part of the main body 500, so that the main body 500 can be easily carried using the handle 530.

Meanwhile, the dust collecting device 600 comprises a first separating element, such as a first cyclone element 610, for separating contaminants from the intake air, a cover 630 connected to the upper part of the first cyclone element 610, and a dust collecting container 620 to which the cover 630 is connected removal.

In detail, the first cyclone element 610 comprises a first air intake hole 611 in the upper side wall. A guide rib 616 is formed on the inner wall of the first air intake hole 611 to direct air passing into the first cyclone element 610 through the first air intake hole 611 approximately tangentially to the inner wall of the first cyclone element 610.

The dust collecting container 620 comprises first and second compartments 624 and 626 for storing contaminants. The first contaminant storage compartment 624 stores the contaminants separated by the first cyclone element 610, and the second contaminant storage compartment 626 stores the contaminants separated by the second cyclone element 700.

The dust collecting container 620 comprises first and second walls 621 and 622. The first wall 621 forms a first compartment 624 for storing contaminants, and the second wall 622 together with the first wall 621 forms a second compartment 626 for storing contaminants.

That is, a second wall 622 surrounds a predetermined portion of the first wall 621 to form a second compartment 626 for storing contaminants. Therefore, a second pollutant storage compartment 626 is formed on the outside of the first pollutant storage compartment 624.

The first wall 621 comprises a curved portion 627 along the circumferential direction to support the lower part of the first cyclone element 610 when the first cyclone element 610 is installed in the dust collecting container 620. Thus, the upper part of the first wall 621 formed above the curved part 627 has a larger diameter, than the diameter of the lower part of the first wall 621 formed under the curved part 627.

Meanwhile, a groove 623 is formed at the upper edge of the dust collecting container 620 for bonding to the first air intake hole 611 of the first cyclone element 610. Therefore, when the first cyclone element 610 is inserted into the dust collecting container 620, the first air intake hole 611 is placed in the groove 623.

The dust container 620 has an open top, so that contaminants collected in the dust container 620 can be easily removed by turning the dust container 620 upside down. The cover 630 is removably connected with the open top of the dust container 620.

The cover 630 includes an inlet 631 for the intake of pollutant particles through which the pollutant particles separated by the second cyclone element 700 pass into the second compartment 626 for storing the pollutant particles.

In addition, a blocking element 614 is provided in the lower part of the first cyclone element 610 as an integral part of the first cyclone element 610 to prevent scattering of the contaminants collected in the first section 624 for storing the contaminants as a result of the swirling movement of air in the first cyclone element 610.

The blocking element 614 comprises an opening 615 through which the contaminants separated from the air in the first cyclone element 610 are discharged into the first compartment 626 for storing the contaminants.

In addition, preferably, the dust collecting device 600 includes a sealing member 640 to prevent air leakage between the first cyclone element 610 and the first wall 621.

In detail, the sealing element 640 is mounted either on the dust collecting container 620 or on the first cyclone element 610. For example, the sealing element 640 can be mounted on the bent portion 627 of the dust collecting container 620 or on the bottom of the first cyclone element 610.

In this embodiment, the sealing element 640 has a circular shape that is continuous along the lower edge of the cylindrical first cyclone element 610. The sealing element 640 is tightly attached to the curved portion 627 for hermetic sealing.

Therefore, air from a place other than the first cyclone element 610 cannot pass into the first compartment 624 for storing contaminants, and air can more efficiently swirl in the first cyclone element 610.

Although embodiments of the present invention have been described with respect to container-type vacuum cleaners, the present invention can also be applied to other types of vacuum cleaners, such as a vertical type vacuum cleaner and a robot vacuum cleaner.

Those skilled in the art will understand that various modifications and changes to the present invention are possible. Thus, it is intended that the present invention include such modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Claims (22)

1. Dust separation device containing: a dust collecting container in which a compartment for storing contaminant particles is formed; a cyclone element contained in a dust container; and a lid connected to the cyclone element and used to selectively open or close the compartment for storing contaminants, moreover, the cover is made with the possibility of detachment from the dust container with the cyclone element. 2. The dust separating device according to claim 1, wherein the pollutant storage compartment comprises a first pollutant storage compartment and a second pollutant storage compartment, and the pollutant particles separated by the cyclone element are stored in the first pollutant storage compartment. 3. The dust separation device according to claim 2, in which the first compartment for storing pollutant particles and the second compartment for storing pollutant particles are separated from each other. 4. The dust separation device according to claim 3, further comprising a sealing element for sealing the cyclone element and a first compartment for storing contaminant particles. 5. The dust separating device according to claim 2, in which the outer wall of the cyclone element contained in the dust collecting container separates the dust collecting container into a first compartment for storing polluting particles and a second compartment for storing polluting particles. 6. The dust separation device according to claim 5, further comprising a sealing element for sealing the first compartment for storing pollutant particles and a second compartment for storing pollutant particles. 7. The dust separating device according to claim 2, in which the second compartment for storing polluting particles is formed on the outside of the first compartment for storing polluting particles. 8. The dust separation device according to claim 2, in which the dust collecting container comprises a curved portion for supporting the cyclone element. 9. The dust separating device of claim 8, wherein the curved portion is rounded. 10. The dust separation device according to claim 2, wherein the lid simultaneously opens or closes the first and second compartments for storing contaminants. 11. A dust separation device according to any one of claims 2 to 10, wherein the cyclone element is a first dust separation element, wherein the dust separation device further comprises a second cyclone element located outside the dust collecting container and selectively communicating with a second compartment for storing contaminant particles, the contaminant particles being separated by a second dust separation element, stored in a second compartment for storing contaminants. 12. A dust separation device according to any one of claims 2 to 10, wherein the cyclone element comprises a blocking element at the bottom to prevent scattering of the pollutants stored in the first compartment for storing the particles, the blocking element comprising an opening for discharging the pollutants separated by the cyclone an element. 13. A vacuum cleaner containing: a dust collecting container in which a first compartment for storing contaminant particles and a second compartment for storing contaminant particles are formed; a first dust separation element located in a first compartment for storing contaminant particles; a lid connected to the first dust separation element and used to selectively open and close compartments for storing contaminant particles; and the main body with which the dust container is connected with the possibility of removal. 14. The vacuum cleaner according to item 13, in which the dust collecting container comprises a first wall forming a first compartment for storing polluting particles and a second wall forming a second compartment for storing polluting particles together with the first wall. 15. The vacuum cleaner according to item 13, in which the dust collecting container contains a curved part for supporting the first dust separation element. 16. The vacuum cleaner according to item 13, further comprising a second dust separating element provided in the main body and selectively connected to the second compartment for storing particulate matter, in which the polluting particles separated by the second dust separating element are stored in a second compartment for storing the polluting particles. 17. The vacuum cleaner according to clause 16, further comprising an opening for the intake of contaminant particles formed in the dust container or in the lid to allow the passage of pollutant particles separated by the second dust separation element into the second compartment for storing the pollutant particles. 18. A vacuum cleaner containing: a dust collecting container in which a compartment for storing contaminant particles is formed; a first dust separating element located in the dust collecting container, an outer wall of the first dust separating element separating a compartment for storing contaminant particles into a first compartment for storing contaminant particles and a second compartment for storing contaminant particles; a lid connected to the first dust separation element and used to selectively open and close compartments for storing contaminant particles; and the main body with which the dust container is connected with the possibility of removal. 19. The vacuum cleaner according to claim 18, wherein the contaminants separated by the first dust separation element are stored in a first compartment for storing the contaminants. 20. The vacuum cleaner according to claim 19, further comprising a second dust separating element provided in the main body and selectively communicating with a second compartment for storing particulate matter, in which the polluting particles separated by the second dust separating element are stored in a second compartment for storing particulate matter. 21. The vacuum cleaner according to claim 19, further comprising a sealing element for sealing the first compartment for storing contaminant particles and a second compartment for storing contaminant particles. 22. The vacuum cleaner according to claim 19, in which the dust collecting container comprises a curved part for supporting the first dust separating element, the curved part being made in a rounded shape.

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